FI70379B - ANORDINATION FOR STORAGE SUPPLY OF A CORNER- ELLER STYCKEFORMIGTMATERIAL - Google Patents

Description

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(51) Kv.lk.4 / lnt.CI. «B 07 B 1/12 FINLAND—" FIN LAND (21) Patent application— PatentansÖkning 783385 (22) Filing date - Ansöknlngsdag 07.11 78 m) '' (23) Starting date - Giltighetsdag 07.11.78 (41) Become public - Blivit offentlig ig g ^ yg

National Board of Patents and Registration of Finland To see ™ ,, and date of publication -? 7 n / ftA

Patent and registration authorities '' Ansökan utlagd och utl.skriften publicerad ^ /. Uj.00 (86) Kv. application - Int. ansökan (32) (33) (31) Privilege claimed — Begärd priority 09.11 .77 31.01.78, i3.O9.78 Sweden i-Sver i ae (SE) 771267 * 4-6, 7801161-6, 7809646-8 ( 71) Rader Companies, Inc., 6005 NE 82nd Avenue, P.O. Box 20128,

Portland, Oregon 97220, USA (72) Gunnar Lindberg, Järfälla, Sweden-Sverige (SE) (7 **) Berggren Oy Ab (5 * t) Grain or piece size of the substance

Anordning for storleksuppdelning av korn- eller styckeformigt material

The invention relates to a device for sizing a granular or lump-like substance, in particular wood chips. The device has a channel for the substance, which is delimited at the bottom by a plurality of rotatably driven material carriers arranged in a row, preferably with res-arranged plates. The single-row media carriers then engage with clearance between the media carriers of the nearest rows on both sides so that the media carriers together form a screen extending along the channel from the inlet of the material to be screened to the outlet for the material, e.g.

Such devices are already known as plate screens, the axes of the plate rows being arranged transversely against the feed-through direction through a channel bounded downwards by the plate rows.

The object of the invention is to provide a device of the kind mentioned at the beginning, which is superior to its previously known forms in terms of the purity of the sorted fractions and which allows embodiments which allow sorting into several different fractions along a sieve.

70379

The desired result is achieved by giving the device the features which appear from the following claim 1.

Such a device acts as a self-cleaning screen for the treatment of wood chips and the like. However, it is possible that a highly adhesive could cause cleaning problems. It is therefore a further object of the invention to provide a device with clearly improved self-cleaning properties.

The substance to be screened in the device may, for example, have variable properties due to varying temperature and humidity, in which case it may, above all, have a variable rolling angle. Such variations affect the screening properties and thus the screening efficiency to a particularly large extent. Another object of the invention is therefore to provide a device of the type mentioned at the beginning, which can be adapted to varying material properties in order to achieve the highest possible screening efficiency.

Some embodiments of the device according to the invention will be explained in more detail below with reference to the accompanying drawings.

Figure 1 shows a top view of a first embodiment of the device.

Figure 2 shows an abbreviated and partially cut-away side view of the same embodiment.

Figure 3 shows a cross-section along the line III-III in Figure 2. Figure 4 shows a vertical cross-section of the trough-like material channel of the device in another embodiment.

Figure 5 shows a partially sectioned side view of the device of Figure 4.

The device shown in Figures 1-3 is a chip screen with a body 1, which at the same time forms the screen casing.

The chip entry point 2 is fitted at one end of the casing and the coarse chip exit point 3 at its opposite end. At the bottom of the jacket there is an outlet 4 for material dropped through the sieve for both first-class chips and screened chips.

Between the inlet point 2 and the outlet point 3 there is a channel 5 delimited from below by a large number of plates 7 arranged in several rows 6. The plates 7 of each row are arranged on a common shaft 8 and are actuated thereby only by means of actuators 9 shown schematically in the drawing. The plates of each row engage with appropriate clearance in the spaces between the plates of the adjacent row or adjacent rows on either side, so that the plates together form a self-cleaning screen running along the channel.

The shafts 8 of the plate rows 6 are oriented in the direction of material passage of the channel 5 and are arranged, in cross-section as shown in Fig. 3, so as to place the plates in a trough-like formation. The bottom of the duct and - for different heights - its sides are then bounded by rows of plates 6.

The plates used in such a direction of rotation (shown by arrow A) that the circumferential motion, wherein the limiting channel 5, there may through the plates or be limited to the chip flow channel rotation transverse to the channel against the other side and up along it (indicated by arrow B), the chip flow moving at the same time 3 towards the outlet point . The raised material falls inwards and downwards towards the plates and the rotational movement is repeated so that the coarse chips, which cannot fall down through the screen, form a helical path through the channel 5 and are effectively separated from the finer chips and screened chips.

The device shown in Figures 4 and 5 is a cell screen for cellulose chips. The rolling angle of the chips varies e.g. depending on the season, depending on whether the chips are frozen or not, and is also affected by the moisture content of the chips.

The plate screen has a body 31 with a chip inlet in the end plate 33. The chip inlet consists of a top open hopper 34 extending from the outside of the end plate at its bottom and sidewalls into the opening 32. At the opposite end is a coarse chip removal point 35. The device is open at a lower point 36 for the removal of first-class chips and screened chips that have fallen through the screen.

Between the inlet 34 and the outlet 35 is a channel bounded at the bottom and sides by a large number of plates 39 arranged in a plurality of rows 38. In the embodiment shown, there are ten such rows 38 parallel and directed in the chip feed direction of the channel 37.

The plates 39 of each row 38 are arranged on a common shaft and are driven therewith by means of a sprocket at the other end of the shaft. The plates of each row 39 engage with appropriate clearance in the spaces between the plates of the adjacent row or adjacent rows on either side so that the plates together form a self-cleaning screen extending along the channel.

The axes of the plate rows 38 are arranged in cross-section as seen in Figure 5 so as to place the plates in a trough-like formation. The plates are driven in such a direction of rotation that their circumferential movement, in which they delimit the channel 37, circulates the chip current on or adjacent to the plates transversely to the other side of the channel and upwards as the chip stream moves simultaneously to the outlet 35. The raised material falls inward-down toward the plate forming the bottom of the channel, and the rotational motion is repeated so that the coarse chips, which cannot fall down through the screen, form a helical path through the channel 37 and are effectively separated from the finer chips and screened chips.

It can be seen from Figure 4 that the two middle rows of plates 38 are fixed and that the others are arranged in two groups A and B, each of which consists of adjacent rows of plates. Thus, in each half of the device, four rows located therein are arranged as a movable group. In each such group, the rows are adapted to be moved together for varying adjustment of the shape and size of the cross-section receiving the chips of the channel 37. For this purpose, the plate rows 38 of each group A and B are supported at each end by support members 41 which can pivot about the axis of their own fixed plate row. Thus, all rows of plates in each group can be moved simultaneously by turning the support members 41 around their pivot axis line 42. Group B is shown in Figure 5 in its lowest calculated position and group A in its highest position. For adjustment, the support members 70379 are provided with pivotally mounted adjusting screws 43 which, via nuts 44, rest on the bottom beam 45 of the body 31. The end plate 33 has recesses 46 for the driven ends of the shafts of the rows 38 so that the plate groups can be turned upwards

In contrast to the one shown here, the device may be provided with only one adjustable group of disc rows, especially if all the discs are used in the same direction to lift the chips only along the other side of the channel. The group or groups of adjustable rows also need not be fitted to the pivoting members. Rows that can be moved in a straight line by means of piston-cylinder devices can also be used as a group or separately in other ways, e.g.

All the rows of plates can be suitably adapted to be adjusted together with respect to their inclination with respect to the horizontal when viewed in the channel feed-through direction. In this way, the through-feed rate can be adjusted. The drawings do not show the devices used for such adjustment.

The plates, with the exception of the toothing shown in Figure 3, are shown as round with a smooth circumference, but may be grooved, corrugated, or toothed, or may have any shape that carries and directs the substance. Their bearings can also be eccentric. The similar placement of similar plates in each row with respect to toothing or the like results in an axial orientation of the elongate objects and prevents them from falling through the screen.

The plates can be suitably arranged in gradual or successive increments along the channel from the point of entry to the point of exit, so that different fractions can be removed from different points under the screen. Also, the size of the plate, usually the diameter, may suitably vary gradually for groups of plates.

The plates can also be exchanged for other types of material carriers, in particular for screening other substances, for example belts running over wheels on pairs of axles, each other such substance-carrying belt passing over the wheels on the other side with a bordering axle and intermediate belts on an axis bounded on the opposite side so that the belts of each row engage in the spaces between the belts of the adjacent row or rows.

In addition, in the embodiment according to Figures 1-3, the plates or other carriers of the substance can be arranged substantially at the same height along both sides of the channel 5, being used in different directions on different sides of the channel centerline, namely from the center of the channel. upwards, whereby the rotational motion is divided into two opposite motions.

Claims (7)

7 70379 An apparatus for sizing granular or aggregate material, in particular for screening chips, the apparatus comprising a channel (5, 37) for the material, which is limited at the bottom by a large number of rotatably driven material supports (7, 39) arranged in rows (6, 38) , preferably aside plates, wherein the media supports of one row (6, 38) engage in clearance between the media supports (7, 39) of the nearest rows (6, 38) on both sides so that the media supports together form a screen extending into the channel (5, 37). ) from the inlet (2, 32) of the substance to be screened to the outlet (3, 35) for the substance, e.g. coarse chips that are too coarse to fall through the screen, the longitudinal axis lines of the substance support rows (6, 38) being directed to the substance (5, 37) in the feed-through direction, characterized in that said axis lines place the material supports (7, 39) in a trough-like formation, so that the bottom of the channel (5, 37) and at least one of its sides such material carrier rows, wherein the material carriers (7, 39) on different sides of the centerline of the channel (5, 37) are adapted to rotate either in the same direction or in opposite directions to rotate the screened material transversely to one or both sides of the channel and upwardly through the channel towards the outlet point (3, 35). Device according to claim 1, characterized in that at least one group (A, B) of adjacent rows (38) of material supports (39) is adapted to vary the shape and size of the material-receiving cross-section of said channel (37). Device according to Claim 2, characterized in that the support members (41) supporting the groups (A, B) of the movable material support rows (38), the support members of one group (A, B) being pivotable by a pivot center line (42) parallel to the longitudinal lines of the rows (38). ) around the entire group (A, B) for simultaneous transfer by turning the support members (41) of the group. Device according to Claim 3, characterized in that it has two groups (A, B) of movable material support rows (38), the pivot axis line (42) of each group being arranged on the axis of the solid material support row (38) at the bottom of the channel. 8 70379 Device according to one of Claims 1 to 4, characterized in that the material carriers (7, 39) are plates arranged in each row on a common, used shaft (8), and in that these plates (7, 39) are round. and preferably toothed. Device according to one of Claims 1 to 5, characterized in that the distribution between the material carriers (7, 39) increases along the channel from the inlet (2, 32) to the outlet (3, 35), so that different fractions can be removed in different ways. align under the sieve. Device according to one of Claims 1 to 6, characterized in that the material support rows (6, 38) are arranged to be adjustable with respect to their inclination in a horizontal plane as seen from the feed direction of the channel (5, 37).